Towards Resilience and Sustainability for Historic Buildings: A Review of Envelope Retrofit Possibilities and a Discussion on Hygric Compatibility of Thermal Insulations
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Vasco Peixoto de Freitas | Magda Posani | Maria do Rosário Veiga | V. P. de Freitas | M. Veiga | Magda Posani
[1] N. Ramos,et al. Evaluation of the hygrothermal properties of thermal rendering systems , 2018, Building and Environment.
[2] M. do Rosário Veiga,et al. Lime-Based Mortars: Viability for Use as Substitution Renders in Historical Buildings , 2010 .
[3] O. Lucon,et al. From Kyoto to Paris: Measuring renewable energy policy regimes in Argentina, Brazil, Canada, Mexico and the United States , 2019, Energy Research & Social Science.
[4] S. Liuzzi,et al. Hygrothermal analysis of technical solutions for insulating the opaque building envelope , 2017 .
[5] Staf Roels,et al. Capillary active interior insulation: do the advantages really offset potential disadvantages? , 2015 .
[6] Paola Lassandro,et al. Climate change mitigation: resilience indicators for roof solutions , 2018 .
[7] P. Walker,et al. Moisture buffer potential of experimental wall assemblies incorporating formulated hemp-lime , 2015 .
[8] Anna Laura Pisello,et al. Energy Refurbishment of Historical Buildings with Public Function: Pilot Case Study , 2014 .
[9] Rosário Veiga,et al. Traditional methods of mortar preparation: The hot lime mix method , 2011 .
[10] Grzegorz Łagód,et al. Properties of hydrophobised lightweight mortars with expanded cork , 2017 .
[12] Iana Vassileva,et al. European Initiatives Towards Improving the Energy Efficiency in Existing and Historic Buildings , 2015 .
[13] S. Pavía,et al. Thermal performance of a selection of insulation materials suitable for historic buildings , 2015 .
[14] Ulrich Filippi Oberegger,et al. Energy retrofit and conservation of a historic building using multi-objective optimization and an analytic hierarchy process , 2017 .
[15] Sara Pavia,et al. Moisture transfer and thermal properties of hemp–lime concretes , 2014 .
[16] Ruut Hannele Peuhkuri,et al. Effect of façade impregnation on feasibility of capillary active thermal internal insulation for a historic dormitory – A hygrothermal simulation study , 2016 .
[17] P. Lassandro,et al. Façade retrofitting: from energy efficiency to climate change mitigation , 2017 .
[18] Robert Černý,et al. Effect of moisture content on heat and moisture transport and storage properties of thermal insulation materials , 2012 .
[19] Fabio Fatiguso,et al. Methodological framework for assessment of energy behavior of historic towns in Mediterranean climate , 2017 .
[20] Targo Kalamees,et al. Heat, Air and Moisture Transfer Terminology : Parameters and Concepts , 2012 .
[21] Umberto Berardi,et al. Hygrothermal characteristics of aerogel-enhanced insulating materials under different humidity and temperature conditions , 2018 .
[22] Darryl J. Newport,et al. Hygric properties of hemp bio-insulations with differing compositions , 2014 .
[23] Maria Philokyprou,et al. Thermal performance assessment of vernacular residential semi-open spaces in Mediterranean climate , 2017 .
[24] D. Bozsaky. Application of Nanotechnology-Based Thermal Insulation Materials in Building Construction , 2016 .
[25] Dominique Derome,et al. Moisture storage and transport properties of preservative treated and untreated southern pine wood , 2016 .
[26] Thomas S. Blight,et al. The use of Passive House Planning Package to reduce energy use and CO2 emissions in historic dwellings , 2014 .
[27] Cristina Cornaro,et al. Dynamic simulation and on-site measurements for energy retrofit of complex historic buildings: Villa Mondragone case study , 2016 .
[28] Robert F. Boehm,et al. Passive building energy savings: A review of building envelope components , 2011 .
[29] M. Moens,et al. First Report of the Cereal Cyst Nematode Heterodera latipons on Wheat in Morocco. , 2012, Plant disease.
[30] Jan Carmeliet,et al. A Comparison of Different Techniques to Quantify Moisture Content Profiles in Porous Building Materials , 2004 .
[31] B. Perrin,et al. Characterization of hygrothermal properties of wood-based products – Impact of moisture content and temperature , 2014 .
[32] Pascal Henry Biwole,et al. Hygrothermal performance of exterior walls covered with aerogel-based insulating rendering , 2014 .
[33] Giuseppina Ciulla,et al. An overview of energy retrofit actions feasibility on Italian historical buildings , 2017 .
[34] Paul Cooper,et al. Existing building retrofits: Methodology and state-of-the-art , 2012 .
[35] S. Balibar. Energy transitions after COP21 and 22 , 2017 .
[36] Staf Roels,et al. Interior insulation for wall retrofitting - A probabilistic analysis of energy savings and hygrothermal risks , 2015 .
[37] Gianpiero Evola,et al. Thermal and Economic Analysis of Renovation Strategies for a Historic Building in Mediterranean Area , 2017 .
[38] Marianna Rotilio,et al. Improving the energy-efficiency of historic masonry buildings. A case study: A minor centre in the Abruzzo region, Italy , 2014 .
[39] Pierre Michel,et al. Experimental assessment of thermal inertia in insulated and non-insulated old limestone buildings , 2014 .
[40] Julien Chamoin,et al. Hygric and thermal properties of hemp-lime plasters , 2016 .
[41] S. Sen,et al. First Report of Alternaria dianthicola Causing Leaf Blight on Withania somnifera from India. , 2007, Plant disease.
[42] Francesco Causone,et al. Energy retrofit for a climate resilient child care centre , 2016 .
[43] Tor Broström,et al. User-driven energy efficiency in historic buildings : A review , 2017 .
[44] Giuseppe Peter Vanoli,et al. Design the refurbishment of historic buildings with the cost-optimal methodology: The case study of a XV century Italian building , 2015 .
[45] Claudia Sicignano,et al. Integrated Methodologies Energy Efficiency of Historic Buildings , 2017 .
[46] Jesper Arfvidsson,et al. Using Typical and Extreme Weather Files for Impact Assessment of Climate Change on Buildings , 2017 .
[47] Maria Concetta Di Tuccio,et al. Characterization and thermal performance evaluation of infrared reflective coatings compatible with historic buildings , 2018 .
[48] Maria do Rosário Veiga. Conservation of Historic Renders and Plasters: From Laboratory to Site , 2012 .
[49] Dionysios I. Kolaitis,et al. Comparative assessment of internal and external thermal insulation systems for energy efficient retrofitting of residential buildings , 2013 .
[50] J. Brito,et al. Studies in ancient gypsum based plasters towards their repair: Mineralogy and microstructure , 2019, Construction and Building Materials.
[51] M. Guizzardi. Hygrothermal Performance Assessment of Novel Interior Insulation Solutions , 2014 .
[52] Sukumar Natarajan,et al. Thermal inertia of heavyweight traditional buildings: experimental measurements and simulated scenarios , 2017 .
[53] M. Zauer,et al. Water absorption of untreated and thermally modified sapwood and heartwood of Pinus sylvestris L. , 2016, European Journal of Wood and Wood Products.
[54] Francesca Cappelletti,et al. Retrofit of an historical building toward NZEB , 2015 .
[55] Francesco Mancini,et al. Energy and environmental retrofitting of the university building of Orthopaedic and Traumatological Clinic within Sapienza Città Universitaria , 2017 .
[56] P. Walker,et al. Determination of hygrothermal parameters of experimental and commercial bio-based insulation materials , 2016 .
[57] Giuseppe Peter Vanoli,et al. Energy retrofit of an educational building in the ancient center of Benevento. Feasibility study of energy savings and respect of the historical value , 2015 .
[58] Giuseppe Peter Vanoli,et al. Energy retrofit of historical buildings: theoretical and experimental investigations for the modelli , 2011 .
[59] Gerardo Maria Mauro,et al. Resilience of robust cost-optimal energy retrofit of buildings to global warming: A multi-stage, multi-objective approach , 2017 .
[60] Ivan Biaggio,et al. 1,1‐Dicyano‐4‐[4‐(diethylamino)phenyl]buta‐1,3‐dienes: Structure–Property Relationships , 2012 .
[61] Staf Roels,et al. Capillary Active Interior Insulation Systems for Wall Retrofitting: A More Nuanced Story , 2016 .
[62] Jianhua Zhao,et al. Evaluation of capillary-active mineral insulation systems for interior retrofit solution , 2017 .
[63] Luisa F. Cabeza,et al. Integration of renewable technologies in historical and heritage buildings: A review , 2018, Energy and Buildings.
[64] Ann Verdonck,et al. Performance of a lime-based insulating render for heritage buildings , 2018 .
[65] Staf Roels,et al. A comparison of the hygric performance of interior insulation systems: A hot box–cold box experiment , 2014 .
[66] A. Magalhães,et al. Caracterización física y mecánica de los morteros antiguos. Aplicación a la evaluación del estado de conservación , 2009 .
[67] Andra Blumberga,et al. Thermal performance of internally insulated historic brick building in cold climate: A long term case study , 2017 .
[68] Tiziano Dalla Mora,et al. Sustainability of a Historical Building Renovation Design through the Application of LEED® Rating System , 2017 .
[69] Giuseppina Ciulla,et al. Redesign of a Rural Building in a Heritage Site in Italy: Towards the Net Zero Energy Target , 2017 .
[70] J. Scartezzini,et al. Effective and robust energy retrofitting measures for future climatic conditions - Reduced heating demand of Swedish households , 2016 .